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Transcript of Glass Armour and Shaped Charge Jets - index-of.co.ukindex-of.co.uk/Tutorials-2/Glass Armour and...
Summary
115 mm shaped charges were ®red at a constant built-in standoffs of3 caliber against on both sides with steel plate covered glass targetsfrom 0� to 60� NATO angles. The residual jet tip velocities and thedisturbed jet regions have been analyzed from double ¯ash X-raypictures of the residual jet behind the target. Surprisingly under smallangles the tip regions and under large angles the residual jet velocityregions have been more disturbed. This can be explained by the factthat under small angles the closure effect of glass is ef®cient but nomore under large angles. But here the cover plates of the glass sand-wich are effective as bulging armour. From the penetration timemeasurements, compared to the theoretical penetration potential, andtogether with the jet fan the jet velocities, which are no more perfectlypenetrating can be de®ned. From this can be derived an induction timeor how fast the armour will start to interfere with the passing jet.
1. Introduction
Glass has some special or so-called abnormal stopping
power against shaped charge jets(1,2). It is demonstrated that
glass has a springback behaviour, respectively very fast
closure effect(1,3). The reason for this is given by the jump
in the Hugoniot curve that glass is compressed to a higher
density and less volume con®guration under pressure which
goes back immediately or at least very fast after the high
pressure is relieved.
It has been known for a long time that glass has a rela-
tively high effectiveness at zero degree incidence but
reduced effectiveness under oblique angles(4). Figure 1
shows the TE effectiveness as a function of glass thickness
under different angles. The TE factor is decreasing once
with increasing glass thickness but is drastically more
reduced if 1" or 2" thick glass plates are oriented at oblique
angles to the jet path. For this early investigation small
caliber shaped charges of nowadays poor qualityÐso-called
Jet GunsÐwere used and were ®red at 10" standoff.
The question now arises, what would be the stopping
power of with steel plates covered glass targets under dif-
ferent attack angles, if larger shaped charges with much
higher jet tip velocities and much higher precision of the jet
are used.
2. Test Arrangement
The tests used the MILAN K with 115 mm diameter and
1.9 mm copper liner of 50� with a wave shaper. The jet tip
velocity is 9.4 mm/ms and the mean particulation time
around 200 ms.
Glass Armour and Shaped Charge Jets
Manfred Held
TDW-Gesellschaft fuÈr verteidigungstechnische Wirksysteme mbH, D-86523 Schrobenhausen (Germany)
Glaspanzerungen und Hohlladungsstachel115 mm Hohlladungen wurden in 3 Kaliber Abstand gegen Glas-
ziele zwischen 0� und 60� NATOwinkel gesprengt. Mit DoppelroÈnt-genblitzaufnahmen wurden die Reststachelgeschwindigkeiten und diezerstoÈrten Zonen im Stachel nach Zieldurchtritt bestimmt. Bei kleinenWinkeln sind die Spitzenbereichszonen und bei groûen Winkeln diehinteren Zonen des Stachels gestoÈrt. Diese Tatsache kann damit erklaÈrtwerden, daû bei kleinen Winkeln der Kraterkollapseffekt im Glaszieleffektiv ist, was nicht mehr bei groûen Winkeln der Fall ist. BeigroÈûeren Winkeln duÈrften die beiden Abdeckplatten Beul-blechwirkung aufweisen. Aus den Weg-Zeit-Messungen in den Rest-zielplatten kann zusammen mit dem StachelfaÈcher der Beginn derStoÈrung des durchtretenden Stachels ermittelt werden. Hieraus kannauch die sogenannte Induktionszeit, wie schnell eine derartige Pan-zerung zu wirken beginnt, abgeleitet werden.
Figure 1. Jet Guns against covered glass of different thicknesses andangles (Ref. 1).
Blindages en verre et jets de charges creusesDes charges creuses de 115 mm ont eÂte tireÂes aÁ intervalle constant
de 3 calibres contre des cibles de verre inclineÂes entre 0� et 60�OTAN. A l'aide de doubles radiographies-eÂclairs, on a deÂtermine lesvitesses de jets reÂsiduelles et les zones de jet perturbeÂes apreÁs per-foration de la cible. Il est surprenant de constater qu'aux petits angles,ce sont les zones de la pointe, et aux grands angles, les parties arrieÁredu jet qui sont les plus perturbeÂes. Ceci peut s'expliquer par le faitqu'aux petits angles, l'effet d'effondrement du crateÁre dans la cible deverre est ef®cace, ce qui n'est plus le cas aux grands angles. LaÁ, lesplaques de couverture du sandwich de verre sont ef®caces commeblindage aÁ effet PAC. A partir des mesures de peÂneÂtration en fonctiondu temps, compareÂes au potentiel de peÂneÂtration theÂorique, et avecl'eÂventail de jets, on peut deÂterminer le deÂbut de la perturbation du jetpeÂneÂtrant. A partir de laÁ, on peut eÂgalement deÂduire un temps d'in-duction ou la vitesse aÁ laquelle un tel blindage commence aÁ interfeÂreravec le jet.
# WILEY-VCH Verlag GmbH, D-69451 Weinheim, 1998 0721-3115/98/0204±0105 $17.50�:50=0
Propellants, Explosives, Pyrotechnics 23, 105±110 (1998) 105
The charge was ®red against the front surface of the glass
module in a constant standoff of 345 mm or 3 calibers
(Figure 2). The NATO angle was changed from 0� to 60� in
steps of 10� and two charges were ®red additionally at 5�
and 55�. The residual penetration was measured in instru-
mented target blocks of mild steel at 16 caliber distance
behind the glass target, corresponding to 1840 mm. A ®rst
¯ash X-ray picture was made after 1240 mm with a make-
switch and a second picture after 1740 mm from the exit
side of the target. In the mild steel blocks, every 25 mm
make-switches have been installed to get the penetration
time history in the target places.
The warhead, supported by a styrofoam prism, followed
by the glass target, arranged here at 55�, the protecting
cassette for the X-ray ®lm together with intensi®er screens,
the ®rst make-switch in front of a styrofoam tube and a
second make-switch in the tube and ®nally the instrumented
target are visible in Figure 3.
3. Experimental Test Results
Figures 4 to Figure 6 show the two ¯ash X-ray pictures of
the residual jets after the glass module obtained from each
test. The pictures cannot show the details which are found
on the 2 m long ®lm strips. But the jets are differently
disturbed by the glass module as a function of NATO
angles.
The Table 1 gives, in addition, the shaped charge ®ring
number, the NATO angle, the measured residual jet tip
velocities vjRes, the reduction in jet velocities Dvj, the
measured residual penetrations in the mild steel blocks and
®nally the total penetrations of the module in line of sight
and the achieved residual penetrations.
The residual jet tip velocities, analysed from the double
¯ash X-ray pictures, are decreasing with increasing NATO
angles. The reduced jet portions Dvj are therefore slightly
increasing with the NATO angle where constant jet tip
velocity of the MILAN with 9.4 km/s is used (Figure 7).
The line of sight thickness of the glass module increases
from 150 mm at 0� to 300 mm at 60�. So the larger
reduction of the jet of the tip region with increasing angles
can be very well understood. As expected, a nearly linear
relationship exists to the path through the glass target
(Figure 8).
The ¯ash X-ray pictures show the jets are disturbed by
varying amounts along their length. The regions with
greater and lesser disturbance are marked in Figure 9. The
jet tip region is strongly disturbed under attack at small
NATO angles and undisturbed for large NATO angles, but
for these larger angles the residual jets are more strongly
disturbed from 5 km/s on downwards. The disturbances of
the jets between the angles of 20� and 50� are not really
consistent. But, with increasing angle, there is a general
trend for the disturbances to more from the jet tip region to
the residual jet portion. This demonstrates that this glass
target has different defeating mechanisms under zero degree
and large NATO angles.
At zero degree the glass acts as described in Refs. 1±3
with a so-called springback behaviour and closure effect
which is effective only against the jet tip region. The fol-
lowing jet again perforates the `̀ broken'' glass. The residual
jets are then more or less undisturbed.
Under larger attack angles to the glass modules the jet tip
regions are not visibly disturbed. This means glass has
nearly no effectiveness on its own if it is impacted at larger
angles. But the front and rear covers of the glass plate are
acting as a `̀ bulging armour'' or so-called spallation armour
Figure 2. Test setup to see the in¯uence of glass targets to the passing jets by ¯ash X-ray and cratering measurements.
Figure 3. Test setup with the covered glass target under 55�.
106 M. Held Propellants, Explosives, Pyrotechnics 23, 105±110 (1998)
(see Ref. 1). This mechanism which needs more induction
time strongly disturbes the residual jet portions.
The remarkable disturbed jet velocity regions, analysed
from the FXR pictures are summarized in the Table 2.
Stronger disturbances of the jets give smaller residual
penetrations in the witness blocks. This is highlighted by the
tests with 10�, 40�, 55� and 60� angles where the residual
penetration is under 300 mm in the witness blocks (see also
Figure 9).
The measured residual penetrations PRes or the total line
of sight penetrations (PMod� PRes) of Table 1 are shown as
a function of NATO angle in Figure 10. Although the data
have stronger scatter, the diagram shows that the residual
penetration PRes is decreasing with increasing NATO angle.
But if the total perforation-pathÐPMod� PResÐis used then
it appears that these values are more or less constant, i.e.
independent of the NATO angle. This seems a surprising
result.
Figure 5. FXR pictures of jets behind the glass targets of 20�, 30� and 40�.
Figure 4. FXR pictures of jets behind the glass targets of 0�, 5� and 10�.
Propellants, Explosives, Pyrotechnics 23, 105±110 (1998) Glass Armour and Shaped Charge Jets 107
4. Cratering Measurements
In addition the penetration history in the mild steel blocks
at 16 caliber standoff was measured(5). As an example one
time-distance measurement is shown in Figure 11. The
penetration in the mild steel blocksÐwitness platesÐfol-
lows the penetration theory(6) at the beginning up to a jet
velocity of around 6.7 mm/ms. This means from this velo-
city on, the jet deviates from the original axis and no longer
arrives on the crater bottom or contributes further to pene-
tration.
The penetration is drastically reduced as soon as the
cratering diagram deviates from the theoretical prediction of
penetration.
Figure 6. FXR pictures of jets behind the glass targets of 50�, 55� and 60�.
Table 1. Test Results against the Glass Target under Different Angles
SC-No NATO angle vjRes Dvj PRes PRes� PMod
(�) (m/s) (m/s) (mm) (mm)
34290 0 8047 1353 511 664.034291 5 7890 1540 403 556.634373 10 7860 1540 303 458.434374 20 7872 1528 493 655.834376 30 7636 1764 310 486.734375 40 7837 (1563) 255 454.734377 50 7396 2104 408 646.034378 55 7023 2477 235 501.734379 60 6878 2522 268 574.0
Figure 7. Residual jet tip velocities vjRest and consumed jet velocities Dvj.
108 M. Held Propellants, Explosives, Pyrotechnics 23, 105±110 (1998)
The jets are disturbed by the glass target either by the
`̀ glass effect'' or the `̀ bulging effect''. Both effects needs
some time before they are working against the follow on jet
velocities. For considerations the arrival times of the jet
velocities on the target surface are used. This is surely a
simpli®cation. But one can select different points in the
target. Under this conditionÐimpact times on the target
surfaceÐthe time differences between the arrival times of
the jet tip and beginning of a disturbance on the residual
penetration can be simply calculated. A virtual origin dis-
tance Z0 of 423 mm was used. This gives an arrival time tj0of the jet tip of 45 ms. Now the time of disturbance can be
simply calculated by Z0=vj ÿ Z0=vj;0. The time differences,
until disturbances are observed by the cratering measure-
ments, are presented in Table 3, calculated with this
method.
Under small angles the time interval is in the range of
10 ms to 20 ms before a stronger disturbance starts. These
are relatively short times. With an angle of 50� the time
difference is 32 ms which demonstrates that bulging at not
too large angles needs more time. With increasing angle the
times are again a little decreasing as could be expected.
5. Conclusion
A covered glass target is tested under different angles
with so-called precision shaped charge jets. The residual
penetration decreases with increasing angle. The total
penetration path in line of sight seems to be more or less
constant.
It was found by the observation of the jets with ¯ash X-
ray behind the target that at small angles the tip region of
the jet is disturbed and at larger angles the residual jets with
velocities from about 6 mm/ms on. This can be explained if
different defeating mechanisms are assumed. At small angle
the glass with its springback behaviour or closure effect is
only able to disturb the jet tip region, which does not work
at large NATO angles. However, at large attack angles the
front and rear plate of the glass target now works as a
bulging armour. A bulging of the steel plates of this glass
target, driven by the glass layer, needs some time to move.
By measuring the penetration time history, the jet velo-
city can be determined from where it deviates from the
hydrodynamic penetration theory and then read from the jet
fan lines. By using the time difference of arrival time of the
jet tip, to when the jet starts to deviate from the expected
Figure 8. Consumed jet velocities as a function of perforation path inthe glass targets.
Figure 9. Disturbed jet regions and residual penetrations.
Table 2. Essential Disturbed Jet Regions
SC-No NATO Angle Disturbed(degree) jet regions
(km/s)
34290 0 8.05ÿ7.534373 10 7.9ÿ5.334375 40 4.4ÿ2.5*34378 55 5.1ÿ2.5*34379 60 5.0ÿ2.5*
* Observation limit is 2.5 km/s.
Figure 10. Residual penetrations in the mild steel blocks PRes and totalpenetration (PRes� PModule).
Propellants, Explosives, Pyrotechnics 23, 105±110 (1998) Glass Armour and Shaped Charge Jets 109
penetration history, the induction time of the target can be
estimated.
For better understanding, the armour mechanism tests
have to be made with diagnostics from the individual
elements of a target arrangement. As diagnostic tools for
shaped charge jet interactions with armours, ¯ash X-ray
pictures of the residual jets and cratering measurements are
especially useful.
6. References
(1) M. Held, `̀ Armour'', Proceedings of 14th Int. Symposium onBallastics, Quebeck-Canada, Vol. 1 (1993).
(2) U. Hornemann, `̀ The Terminal Ballistic Resistance of Glassagainst Shaped Charge Penetration'', Proceedings of the 11th Int.Symposium on Ballistics, Vol. II, 381±389 (1989).
(3) G. E. Hauver, P. H. Netherwood, R. F. Benck, and A. Melani,`̀ Penetration of Shaped Charge Jets into Glass and CrystallineQuartz'', Technical Report BRL-TR-3273, 1991.
(4) E. M. Pugh, `̀ Defeat of Shaped Charge Weapons'', Final Report,Contract No DA-36061-ORD-507, Figure 19, 1960.
(5) M. Held, `̀ Evaluation of Shaped Charge Penetration Ef®ciency byAdvanced Diagnostik Techniques'', Proceedings of 6th Int. Sym-posium on Ballastics, 1981, pp. 480±493.
(6) M. Held, `̀ Hydrodynamic Theory of Shaped Charge Jet Penetra-tion'', Journal of Explosive and Propellants, R.O.C.-Taiwan, 7, 9±24 (1991).
(Received November 12, 1996; Ms 69/96)
Figure 11. Example of a penetration time measurement together with the jet fan.
Table 3. Time Differences between the Arrival Times of the Jet Tipand the Beginning of a Disturbance
SC-No NATO angle Disturbed vj* Time to Disturbance(degree) (km/s) (ms)
34290 0 8/5.2 8/36.334291 5 6.7 18.134373 10 7.2 13.834374 20 7.2 13.834376 30 6.7 18.134375 40 7.1 14.634377 50 5.5 31.934378 55 6.2 23.234379 60 5.9 26.7
* Derived by cratering.
110 M. Held Propellants, Explosives, Pyrotechnics 23, 105±110 (1998)